WO2019092077A1

WO2019092077A1 - Dc link capacitor module, power electronics module and power electronics device

Info

Publication number: WO2019092077A1
Application number: PCT/EP2018/080564
Authority: WO
Inventors: Arnoud Smit; Daniel Zitzmann; Harald Hofmann
Original assignee: Valeo Siemens Eautomotive Germany Gmbh
Priority date: 2017-11-10
Filing date: 2018-11-08
Publication date: 2019-05-16
Also published as: US20210110978A1; CN111344823A; EP3707737A1; DE102017126394A1; CN111344823B; US11417470B2; JP2021502702A; EP3707737B1

Abstract

The invention relates to a DC link capacitor module (1, 1'), in which a coil (4, 5) is electrically conductively attached to two mutually opposite electrode plates (2a, 2b), wherein a plurality of first connecting means (6) are provided on each electrode plate (2a, 2b) to produce a detachable or non-detachable plug-in connection to second connecting means (9a, 9b), which correspond thereto and are attached to a bus bar (7a, 7b) of a power electronics module (8).

Description

DC link capacitor module, power electronics module and power electronics device

The invention relates to a power electronics device, in particular for use in electric vehicles. It further relates to a DC link capacitor module and a power electronics module, which are suitable for the production of the power electronics device. In the prior art, power electronic devices, such as charging devices for energy storage, inverter or DC-DC converter are well known. Such a power electronic device comprises a DC voltage intermediate circuit with an intermediate circuit capacitor. In power electronics devices with direct voltage intermediate circuit, which are provided for example for applications in vehicles with combined or exclusively electric drive, very powerful power semiconductors or power semiconductor modules are often used.

These are able, by means of partially complex control methods and suitable control methods, to switch large electrical powers as needed by means of high switching speeds. However, the fast switching of high currents at the DC intermediate circuit in combination with design-related inductances, in particular line inductances, during a turn-off operation of the power semiconductor or power semiconductor modules often leads to undesirable voltage spikes. Most cause high-frequency switching operations of power semiconductors or power semiconductor modules at the DC intermediate circuit from impairments of electromagnetic compatibility. It is known to counteract these unwanted electrical effects with the use of the DC link capacitor in the DC intermediate circuit. Decisive for the success of this measure, it is in particular that means the best possible electrical and mechanical connection of the DC link capacitor to the power semiconductor or the power semiconductor modules is produced. An intermediate circuit capacitor is usually formed from two opposing electrode plates, between which one or more coils are held. Each winding has two opposite end faces, which are electrically contacted by Schoopierung. The schoopierten end surfaces are usually soldered or welded to the respective electrode plate. The electrode plate in turn is in turn fixedly connected to a bus bar, which has a connection element for connection to an external circuit, line or the like. In certain embodiments, the electrode plate with the coils held therebetween and the bus bars, with the exception of the connection elements provided therein, are encapsulated with a potting compound. DC link capacitors are usually purchased from manufacturers of power electronic devices from suppliers who manufacture the DC link capacitors according to the manufacturer's specifications. When changing the specification of a manufacturer, it is therefore necessary that the supplier manufactures a separately adapted intermediate circuit capacitor separately. That's awkward and time-consuming.

The object of the invention is to eliminate the disadvantages of the prior art. It should be specified in particular a power electronics device, which can be produced with reduced effort.

This object is solved by the features of claims 1, 6 and 1 1. Advantageous embodiments of the invention will become apparent from the features of the dependent claims. According to a first aspect of the invention, an intermediate circuit capacitor module is proposed in which a winding is attached to two opposing electrode plates in an electrically conductive manner, wherein on each electrode plate a plurality of first connecting means are provided for producing a detachable or non-detachable plug connection with corresponding thereto, attached to a busbar of a power electronics module second connecting means.

The proposed intermediate circuit capacitor module has no busbars in deviation from the prior art. Only first connection means are provided on each electrode plate, which are suitable for connection to second connection means provided on the busbars. This makes it possible to mount the busbars with the second connection means provided thereon in the power electronics module and then to electrically connect the intermediate circuit capacitor module to the busbars in a later manufacturing step by means of a simple plug connection. The intermediate circuit capacitor module may have further electrically conductively attached to the electrode plates winding. Depending on the requirements of the manufacturer of power electronic devices, the intermediate circuit capacitor module may be provided by the supplier with a different number of windings and / or windings of different properties. Independently of this, the geometry of the electrode plates as well as the arrangement and design of the first connecting means can be maintained. It is thus possible on the manufacturer side, while maintaining the mounting geometry of the power rails mounted on the power electronics module, to quickly and easily mount intermediate circuit capacitor modules which, for example, have a different capacitance. The supplier eliminates the costly and time-consuming step of mounting the busbar to the electrode plates. Apart from this, such intermediate circuit capacitor modules can also be provided in smaller units on the supplier side, of which then several can be mounted by the manufacturer on the busbars by means of the plug connection.

According to a particularly advantageous embodiment, the first connecting means is formed integrally with the electrode plate. The first connection means can be made for example by means of stamping, laser cutting and bending technology in one piece with the electrode plate. The first connection means may in particular be designed in the manner of a socket or tab suitable for receiving a contact pin. The bushing or tab can, for example, have a clamping spring or the like.

According to a further advantageous embodiment, a first electrode plate pair formed from the electrode plates with the first winding received therebetween and a second electrode plate pair formed from two other opposing electrode plates are provided in parallel arrangement with one or more second windings received therebetween. The proposed subdivision of the intermediate circuit capacitor module in a first and a second pair of electrode plates, each with held between coils allows while maintaining a predetermined geometry, a reduction of the spanned between the electrode plates surfaces. As a result, a leakage inductance of the DC link capacitor module is lowered. Such a DC link capacitor module is suitable for particularly fast switching operations. According to a second aspect of the invention, a power electronics module with at least two busbars is proposed, wherein on each busbar second connecting means for producing a detachable or non-detachable plug connection with corresponding thereto, attached to a DC link capacitor module according to the invention first connection means are provided.

The proposed power electronics module can advantageously be produced by the manufacturer initially without the intermediate circuit capacitor module. It can be connected in a later manufacturing step quickly and easily by producing a plug-in connection with the intermediate circuit capacitor module according to the invention. As a result, it is possible, for example, to mount the bus bars by the manufacturer so that they are close to a cooling device attached or in direct contact with a cooling device. The busbars may each be provided with a standardized arrangement of second connecting means. This makes it possible to mount one or more geometrically adapted intermediate circuit capacitor modules to the busbars.

The busbars may be mounted in opposing arrangement, in particular sandwiched. A bus bar may have openings for passing through the second connection means of the other bus bar.

According to an advantageous embodiment, the second connection means is designed in the manner of a contact pin extending from the busbar, which contact pin is frictionally inserted into the first connection means. The term "contact pin" is to be understood in the present general, d. H. It may also be one or more adjacent juxtaposed contact tongues, which are formed, for example, in plan view rectangular, trapezoidal or tapered. The contact pin can also be designed as a pin or pipe socket. It can be round, square or rectangular in cross-section. The second connecting means is expediently formed integrally with the busbar. The second connecting means may be formed, for example, by means of stamping, laser cutting and bending.

The busbar may have a connection element for connection to a supply line, a circuit or the like. This is, for example, a connection lug with an opening for passing through a fastening element, for example a screw, a threaded bolt or the like. Preferably, the power electronics module is designed as a charging device for an electrical energy store, as an inverter or as a DC-DC converter. According to a third aspect of the invention, a power electronic device is proposed, in which an intermediate circuit capacitor module according to the invention is connected by means of a plug connection to the busbars of a power electronics module according to the invention.

Such a power electronics device can be produced with reduced effort. Depending on the requirements, it can also be combined with several DC link capacitor modules of the same or different capacitance, voltage stability, leakage inductance and the like. Furthermore, improved cooling of the DC link capacitor module can be achieved with the proposed separation of the busbars from the DC link capacitor module. The busbars can be factory-mounted in the power electronics module so that they can be cooled with improved efficiency.

The power electronics device according to the invention may further comprise a cover element, which include the coils eindicht gastight. The cover element protects the wraps from moisture and heat, which can damage the wraps, especially during transport. Particularly preferably, the lid member is deformable to allow pressure equalization without gas exchange between the recorded in the interior of the lid member winding and the environment. In particular, it is thus possible to dispense with conventionally used metallized single-use films in which conventional wraps are welded during transport. In addition, the power electronics device may comprise a sealing element sealing the cover element with respect to a busbar. The cover element can rest on the busbar.

According to an advantageous embodiment, a connection produced between the first and the second connection means is detachable or insoluble. A plug connection initially produced for mounting the intermediate circuit capacitor module can, for example, be left as it is. It is then a detachable connection. However, it is also conceivable, for example, to deform the second connection means after the connection has been produced, so that the connection becomes insoluble, ie, it can no longer be released without deformation or destruction of the connection means.

Advantageous embodiments of the invention will be explained in more detail with reference to the drawings. Show it:

1 is a partial perspective view of a first power electronics device,

2 is a partial perspective view of a second power electronics device, Fig. 3a is a perspective sectional view of first and second connecting means in a first position,

3b is a sectional side view of the first and second connecting means in the first position,

Fig. 3c is a sectional perspective view of the first and second

Connecting means in a second position and

Fig. 4 is a perspective view of a power electronic device in an assembled state.

1 shows a DC link capacitor module, generally designated by the reference numeral 1. The DC link capacitor module 1 has a first electrode plate 2 a and a second electrode plate 2 b facing each other and forming a first electrode plate pair 2, and a third electrode plate 3 a and a fourth electrode plate 3 b, which are also opposite each other and form a second pair of electrode plates 3. Between the first pair of electrode plates 2, a plurality of first winding 4 and between the second pair of electrode plates 3 second winding 5 are mounted. The reels 4, 5 are schoopiert frontally. By means of soldering, welding or another connection technique, the winding 4 with the electrode plates 2a, 2b and the winding 5 with the electrode plates 3a, 3b are connected.

The electrode plates 2a, 2b, 3a, 3b are each provided with first connecting means 6. The first connecting means 6 are here formed integrally with the electrode plates 2a, 2b, 3a, 3b, bent tabs.

1 further shows a first busbar 7a and a (here partially hidden) second busbar 7b of a power electronics module 8. The busbars 7a, 7b are sandwiched from one another electrically insulated. From the busbars 7a, 7b extend second connecting means 9a, 9b, which are designed in the manner of a plug-in tab. The extending from the first busbar 7a second connecting means 9a penetrate through openings 10 of the second busbar 7b.

The first connection means 6 and the second connection means 9a, 9b are formed correspondingly for producing a detachable or non-detachable plug connection. An arrangement of the first connecting means 6 on the DC link capacitor module 1 is corresponding to the arrangement of the second connecting means 9a, 9b on the busbars 7a, 7b so that between all the first connecting means 6 and all the second connecting means 9 when placing the DC link capacitor module 1 on the busbars 7a, 7b the connector can be produced.

The first busbar 7a is connected to a first connection element 11a. The second busbar 7b is connected to a second connecting element 11b. The connection elements 1 1 a and 1 1 b each have an opening 12 through which, for example, screws can be guided for connection to power lines. The arrangement of the busbars 7a, 7b shown in FIG. 1 is an integral part of the power electronics module 8. The intermediate circuit capacitor module 1 can be connected by means of the plug connection with the power electronics module 8 to a power electronic device 14.

As can be seen in particular from FIG. 2, with a constant configuration of the busbars 7a, 7b, a further differently configured intermediate circuit capacitor module V, can be connected to the first busbar 7a and second busbar 7b. The further DC link capacitor module V has only a first electrode plate 2a and a second electrode plates 2b, which form an electrode plate pair 2 and between which a plurality of first coils 4 are held. By virtue of the arrangement and design of the busbars 7a, 7b and the second connecting means 9a, 9b provided thereon, the power electronics module 8 being standardized, correspondingly designed intermediate circuit capacitor modules 1, 1 'can thus be constructed with great difficulty with respect to the arrangement and design of the first connecting means Plug connection are connected. However, the DC link capacitor modules 1, 1 'can be designed differently with regard to the number and configuration of the electrode plates 2a, 2b, 3a, 3b and the rolls 4, 5 held therebetween. This makes it possible to combine intermediate circuit capacitor modules 1, 1 'of different capacitance, leakage inductance or the like with the power electronics module 8. 3a shows a perspective, cutaway view of a first connection means 6 attached to an electrode plate (here by way of example the third electrode plate 3a) and a second connection means 9a extending from a busbar (here by way of example the first busbar 7a) in a first position before connection , As can be seen in particular in conjunction with a sectional side view shown in Fig. 3b, the first connecting means 6 is formed here in the manner of a bent tab, which is made in one-piece construction with the first electrode plate 2a. The second Connecting means 9a consists of two tongues extending from the first busbar 7a, which converge at a free end of the first connecting means 6. The first connecting means 6 is frictionally inserted into the second connecting means 9a designed as a tab. 3d shows the intermediate circuit capacitor module 1, which is connected by means of the plug connection to the power electronics module 8 in a second position, the second connection means 9a having been deformed for producing the permanent connection. The releasable connection eliminates the deformation. 4 shows a perspective partial view of a power electronics device 14, which comprises the DC link capacitor module 1 connected to the power electronics module 8 and a cover element 15 in an assembled state. In addition, the power electronics module 8 comprises further power electronics components (not shown), which realize a function as a charging device for an energy store, as an inverter or as a DC-DC converter.

The lid member 15 rests on the second busbar 7b and is sealed by a seal 16 of this opposite. The lid member 15 is deformable, so that a pressure equalization without gas exchange between the winding 4, 5 receiving the interior 17 of the lid member and the environment is possible.

Claims

claims

1 . DC link capacitor module (1, 1 '), in which a winding (4, 5) is electrically conductively attached to two opposing electrode plates (2a, 2b), wherein on each electrode plate (2a, 2b) a plurality of first connecting means (6) for Producing a detachable or non-detachable plug connection with corresponding thereto, on a busbar (7a, 7b) of a power electronics module (8) mounted second connecting means (9a, 9b) are provided.

Second intermediate circuit capacitor module (1, 1 ') according to claim 1, wherein the first connection means (6) are formed integrally with the electrode plate (2a, 2b, 3a, 3b).

3. DC link capacitor module (1, 1 ') according to claim 1 or 2, wherein the first connecting means (6) is designed in the manner of a suitable for receiving a contact pin socket or tab.

4. DC link capacitor module (1, 1 ') according to one of the preceding claims, wherein in parallel arrangement one of the electrode plates (2a, 2b) formed first electrode plate pair (2) with the first coil received therebetween (4) and one of two further opposite Electrode plates (3a, 3b) formed second electrode plate pair (3) are provided with a second winding (5) received therebetween.

The link circuit capacitor module (1, 1 ') according to claim 4, wherein a first electrode plate (2a) of the first electrode plate pair (2) comprises a third electrode plate (3a) of the second electrode plate pair (3), and a second electrode plate (2b) of the first electrode plate pair (2) is connected to a fourth electrode plate (3b) of the second electrode plate pair (3).

6. power electronics module (8) with at least two busbars (7a, 7b), wherein at each busbar (7a, 7b) second connecting means (9a, 9b) for Producing a detachable or non-detachable plug connection with corresponding thereto, on a DC link capacitor module (1, 1 ') according to one of the preceding claims attached first connecting means (6) are provided.

7. power electronics module (8) according to claim 6, wherein the second connecting means (9a, 9b) is formed integrally with the busbar (7a, 7b).

8. power electronics module (8) according to claim 6 or 7, wherein the second connecting means (9a, 9b) in the manner of a of the busbar (7a, 7b) extending contact pin which frictionally in the first connecting means (6) can be inserted.

9. power electronics module (8) according to one of claims 6 to 8, wherein a busbar (7a, 7b) a connection element (1 1 a, 1 1 b) for connection to a

Supply line has.

10. Power electronics module (8) according to one of claims 6 to 9, which is designed as a charging device for an electrical energy storage, as an inverter or as a DC-DC converter.

1 1. Power electronic device (14), in which a DC link capacitor module (1, 1 ') according to one of claims 1 to 5 connected by means of a plug connection with a power electronics module (8) according to one of claims 6 to 10 connected.

12. Power electronics device (14) according to claim 1 1, wherein the plug connection produced between the first connection means (6) and the second connection means (9a, 9b) is detachable or non-detachable.

13. power electronics device (14) according to claim 1 1 or 12, wherein for producing a permanent connection, the second connecting means (9a, 9b) after insertion into the first connecting means (6) is deformed.

14. Power electronics device (14) according to any one of claims 1 1 to 13, further comprising a, in particular deformable, cover element (15), which einhaust the windings (4, 5) gas-tight.

15. The power electronics device (14) according to claim 14, further comprising a sealing element (16) sealing the cover element (15) with respect to a busbar (7a, 7b).